Method of determining accuracy error in line width metrology device

ABSTRACT

A method of determining the accuracy error in scanning signals of a semiconductor line width metrology device comprises the steps of creating a frequency signature template of a patterned feature formed on a semiconductor layer with a line width metrology measurement device that is in nominal operating condition. Another patterned feature similar to the first patterned feature is scanned and the waveform signal is generated of the line width patterned feature. The waveform signal is processed and converted into a frequency signature which is compared with the frequency signature template.

FIELD OF THE INVENTION

This invention relates to the field of line width metrology, and more particularly, this invention relates to a method of determining errors in a line width metrology device.

BACKGROUND OF THE INVENTION

Line width metrology devices, such as a scanning electron microscope, typically do not judge the quality of an output amplitude modulated signal with respect to instrumental error. The scanning electron microscope, produces a profile of the intensity versus position. Most of the information in the past has been taken from an arbitrary position on the waveform to produce the critical dimension of the line width. Most manufacturers have focused on the features that are analyzed, such as a photoresist feature, and not the intensity signal itself, to obtain information about the scanning electron microscope. For example, a problem may exist when the scanning electron microscope (or other metrology instrument) is not in focus and gives a different value of the critical dimension. An out of focus line width metrology device could widen the profile based on the arbitrary position that is picked for the critical dimension width. Thus, it would be advantageous if the critical dimension number was not focused on as in the prior art to determine the operating accuracy error in the scanning electron microscope or similar line width metrology device.

SUMMARY OF THE INVENTION

It is therefore an object of the present invention to provide a method of determining the accuracy error in scan signals of a semiconductor line width metrology device.

In accordance with the present invention, a method of determining the accuracy error in scan signals of a semiconductor line width metrology device, such as a scanning electron microscope, creates a frequency signature template of a patterned feature formed on a semiconductor layer with the line width metrology measurement device that is in nominal operating condition. A similar patterned feature formed on a semiconductor layer is scanned with the line width metrology measurement device for generating a waveform signal of the line width of the similar patterned feature. The waveform signal is processed to convert the signal into a frequency signature. The relative power of the frequency components of the frequency signatures are compared to the frequency signature template and the accuracy of the line width metrology device is determined based on the relative proportions between the frequency signatures of the similar patterned feature and template.

In still another aspect of the present invention, the method comprises the step of determining the relative proportions between the low and high frequencies of the frequency signature template and comparing the relative proportions of the low and high frequencies of the frequency signature template with the frequency signature obtained from the similar patterned feature. The relative proportions of high and low frequencies can be compared to the mid-range frequencies corresponding to the spacing. The high frequencies within the frequency signature template can be compared with high frequencies in the frequency signature obtained from the similar patterned feature. The step of scanning further comprises the step of generating an amplitude modulated waveform signal, such as produced from a scanning electron microscope or a semiconductor stylus measurement tool.

BRIEF DESCRIPTION OF THE DRAWINGS

Other objects, features and advantages of the present invention will become apparent from the detailed description of the invention which follows, when considered in light of the accompanying drawings in which:

FIG. 1 is a drawings showing an enlarged view of a patterned feature and the amplitude modulated waveform signals relative to the patterned feature.

FIGS. 2A and 2B are graphs showing respective well tuned (focused) and poorly tuned (unfocused) amplitude modulated waveform signal produced by a scanning electron microscope.

FIG. 2C is a schematic block diagram showing a scanning electron microscope.

FIG. 2D is a schematic diagram of a stylus line width measurement device.

FIG. 3 is a graph showing a waveform obtained from a scanning electron microscope illustrating a sharp (focused) and not sharp (unfocused) waveform.

FIG. 4 is an image of the actual scan obtained from the scanning electron microscope for the sharp waveform signal of FIG. 3.

FIG. 5 is a graph showing the frequency signature of the sharp waveform signal of FIGS. 3 and 4.

FIG. 6 is an image of the scan from an unfocused scanning electron microscope of FIG. 3.

FIG. 7 is a graph showing the frequency signature for the unfocused waveform signal of FIGS. 3 and 4.

FIG. 8 is a schematic drawing illustrating a photoresist cross-section and waveform signal as generated for normal cross-section, which can be used to form a template.

FIG. 9 is a schematic drawing showing a defective (T-topped) cross-section and the generated waveform signal.

FIG. 10 is a graph of the amplitude modulated waveform signal and showing the line width and line space dimensions.

FIG. 11 is a graph showing the curve generated by the slope obtained from the derivative of the line space and line width.

FIG. 12 is a more detailed graph of a Normal vs. T-topped “X” direction Critical Dimension range for images shown in FIGS. 8 and 9.

FIG. 13 is an image from a scanning electron microscope showing various width and space inflection points and other waveform points from which the analysis based upon the line width is generated.

FIGS. 14 and 15 are both top down critical dimension images of a photoresist feature having a normal or “nominal” and the T-top as shown in FIGS. 8 and 9.

FIGS. 16A through 16C illustrate a normal photoresist feature, a footing, and a topping, respectively.

FIG. 17 are images showing a single critical dimension and etched detection parameter, and how it would indicate a similar width for all structures despite large variations in profile shapes and pattern transfer.

FIGS. 18 and 19 are images showing positive and negative stepper focus, where a thickness reduction is shown in the positive step of focus, and full thickness is maintained in the negative stepper focus.

FIGS. 20A and 20B are graphs showing a photoresist population distribution, and a post etch distribution after adjustment of subsequent etch.

FIGS. 21A and 21B are graphs showing a photoresist shape distribution, and a post etch distribution.

FIG. 22 is a matrix of scale and shape values for a plurality of features, such as shown in the distributions of FIGS. 20A and 21A.

FIGS. 23-39 are graphs illustrating the operation of a scanning electron microscope system where signal segments of a scanned waveform signal use an auto-correlation function to produce an auto-correlation signal, which is then compared with a reference signal.

FIG. 40 is a detailed waveform signal showing how the signal is split by parts, indicative of characteristic surface portions of the patterned feature.

FIGS. 41A through 41C are graphs showing contoured shapes and scale, the templates, and the derived curve of FIG. 41C.

FIG. 42 is a graph illustrating a comparison of an input template and variable signal for a same shape and different scale.

FIG. 43 is a graph illustrating the same scale and different shapes.

FIG. 44 is a graph illustrating a correlation by taking a derivative, which emphasizes the slope and transitions where the amplitude may be normalized.

FIG. 45 is a graph illustrating the detection of specific shapes.

FIG. 46 is a graph illustrating a derivative correlation after normalization, where the amplitude accounts for variations in tool signal gain and similar sharpness.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention is advantageous because it provides a method of determining the accuracy error in scan signals of a semiconductor line width metrology device, such as a scanning electron microscope, or a semiconductor stylus measurement device. The present invention also provides a method for analyzing a semiconductor wafer surface having patterned features on the surface by scanning across a patterned feature and generating an amplitude modulated waveform signal of the line width, and processing the amplitude modulated waveform signal for calculating the scale and shape of the patterned feature based on the profile of the amplitude modulated waveform signal. The calculated scale and shape is then compared with a template of a normal patterned feature having a desired shape and scale. Additionally, this information can be used for adjusting a subsequent etch process based on a population distribution of features to compensate for any defects in the patterned feature.

The present invention also provides a method for analyzing a semiconductor surface having patterned features on a semiconductor layer, such as a photoresist, by scanning at least one patterned feature to produce a scanned waveform signal having signal segments corresponding to characteristic surface portions of the patterned feature. The signal segments are processed using an auto-correlation function to produce an auto-correlation signal for each characteristic surface portion of the patterned feature. A reference signal having signal segments corresponding to characteristic surface portions of a known patterned feature is provided and each segment of the auto-correlation signal is compared to the respective signal segments of the reference signal.

In prior art metrology systems, the scale-of a patterned feature could be determined by line width metrology devices. However, shape was not determined. The present invention analyzes not only the scale, but also the shape of a patterned feature, such as a photoresist feature, which is compared to a template. Also, a distribution of patterned features allows analysis for past etch processing.

Referring now to FIG. 1, a patterned feature 100, such as a photoresist feature, is formed on a semiconductor layer 102. As is known to those skilled in the art, a metrology device (such as a scanning electron microscope) can scan the patterned feature (and preferably an entire distribution of features on the surface) and produce a critical dimension parameter of line width. Although the description will follow with reference to a scanning electron microscope, any semiconductor line width metrology device, such as a semiconductor stylus measurement tool, (FIG. 2D), an optical microscope, an atomic force microscope, a focused ion beam and other electron beam microscopes, as known to those skilled in the art, could be used. FIGS. 1 and 2A illustrates the type of amplitude modulated waveform signal 104 that could be produced based on the shape and scale of a patterned feature 100, in this case, a photoresist feature. FIG. 1 shows a plurality of scan lines across the photoresist feature.

FIG. 2A illustrates a well tuned waveform signal in the form of the amplitude modulated waveform signal, showing a profile of which the Critical Dimension line width of the patterned feature could be determined. The electron scanning microscope was well tuned. The waveform signal includes low frequency components corresponding to the central portion of the patterned feature, mid-range frequency components corresponding to the edge portions, and high frequency components corresponding to the very edge. The edge portions have a higher signal intensity and contain the higher frequency components. A poorly tuned scanning electron microscope would produce a waveform signal, such as shown in FIG. 2B, which has a broader shape and attenuated high frequency components.

FIG. 2C illustrates only one type of scanning electron microscope that can be used to practice the method of the present invention. The scanning electron microscope 110 includes a body 112 with appropriate lenses 114 contained in the body and forming an electron beam channel 116. A high tension supply 118 provides power through the electron beam column formed by the body 112. A lense power supply 120 provides appropriate deflection or control over the electron beam that hits a wafer 122 contained on an electron collector 124. The body 112 forming the column has a maintained vacuum as accomplished through a vacuum system 126. Electrons are collected and sent through a preamplifier 128 and then through a signal amplifier 130 and into a controller 132, which forms the image and can perform processing and calculating of shape and scale in accordance with the present invention. A tool 134 could be adjusted as necessary. The controller 132 also controls scanning circuits 136 and a magnification controller 138. Other electron beam metrology systems using electron beam microscopes are set forth in U.S. Pat. Nos. 4,600,829 issued Jul. 15, 1986; 4,751,384 issued Jun. 14, 1988; and 4,767,926 issued Aug. 30, 1988, the disclosures which are hereby incorporated by reference in their entirety.

FIG. 2D illustrates a stylus measuring device using a controller 139 a, stylus 139 b, and holder 139 c for wafer (W).

FIG. 3 shows a graph of two generated waveforms showing differences between the waveform produced by a sharp and well tuned scanning electron microscope and a scanning electron microscope that is not sharp, i.e., out of focus. The measurements were performed on a photoresist feature formed in a polysilicon semiconductor layer. The well tuned scanning electron microscope produced a 276 nanometer line width, while an untuned (not sharp) scanning electron microscope produced a line width of 283 nanometers. Examples are shown in FIGS. 4 and 6, showing images produced from the scanning electron microscope, where the image from the unfocused scanning electron microscope (FIG. 6) shows a line width having edges that are not well focused, but more spread. In FIG. 4, the edges are more clear.

The frequency signatures are shown in FIGS. 5 and 7 for a respective focused and unfocused scanning electron microscope. The frequency signatures indicate that the higher frequency components in the unfocused microscope are attenuated. As is well known to those skilled in the art, the Fast Fourier Transform (FFT) function can be performed on the amplitude modulated waveform signal, to produce the frequency signatures, as illustrated. In accordance with the present invention, a frequency signature template indicative of a known patterned feature is formed.

The frequency signature template can be formed by scanning a known patterned feature positioned on a semiconductor layer when the SEM is in nominal, i.e., normal, operating condition. The Fourier Transform produces the frequency signature which would be stored in a database 139 (FIG. 2C). A patterned feature formed on a semiconductor layer of a sample having similar patterned features is then scanned with the line width metrology measurement device, i.e., the SEM in this example, and an amplitude modulated waveform signal indicative of the line width of the patterned feature is generated. This waveform signal is then converted into a frequency signature. The relative power of the frequency components obtained from the similar patterned feature is compared to the frequency components of the frequency signature template. The accuracy of the SEM can then be determined based on the relative proportion between the frequency signatures of the template and similar patterned feature.

As shown in FIGS. 5 and 7, the proportion of the higher frequencies in the frequency signature template is greater than the higher frequencies contained in the similar patterned feature. The relative proportions between the low and high frequencies can also be compared with the relative proportions of the low and high frequencies of the frequency signature template. The relative proportions of high and low frequencies can be determined with the mid-frequencies corresponding to the inner line spacing.

It is well known that line width metrology tools traditionally do not judge the quality of the output amplitude modulated signal with respect to any instrument error. Low frequency components are used for the measurement. The mid to high frequencies are typically not used. As noted before, in accordance with the present invention, the higher frequency components can be used to determine if the scanning electron microscope (or other line width metrology device that generates a preferred amplitude modulated waveform signal) is accurate with respect to the known samples. It is not possible to distinguish accurately an increase in width based only on the low frequency components of the measurement. Thus, the mid and high frequency components of a frequency signature template derived from a known sample are used for a comparison.

The illustrated images and produced waveforms set forth in FIGS. 3-17 were obtained from a Hitachi S-8820 CD SEM (Critical Dimension Scanning Electron Microscope). The image in FIG. 6 was taken of a photoresist line-patterning gate in a routine automated production measurement step. The image of FIG. 4 was taken after an engineer optimized the tool using standard procedures. It is evident that the image in FIG. 6 is hazy or fuzzy and resulted in an inaccurate CD (critical dimension) line width measurement of 283 nanometers. The image of FIG. 4 is sharper. It is shown as the thinner line in FIG. 3 and represents the 276 nanometer line width. The width differential accuracy is a substantial portion of the process line width tolerance and is in addition to any precision metrology errors. The width is defined by the first differential edge position. Two hundred vertical sum lines were used with no signal smoothing.

It is evident that when the sharper (i.e., in focus) signal is compared with the fuzzy or unfocused signal, a substantial proportion of the high frequency components have been replaced with lower frequency components. The very high frequencies are attenuated. The width has also been increased significantly. Thus, it is seen that the accurate increase in CD line width of the unfocused signal can be differentiated from the sharper signal with the same critical dimension width. Thus, the sharp (i.e., focused) and fuzzy (i.e., unfocused) signals have different frequency signatures, independent of normal process width variations. This information can be used with appropriate software as determined by those skilled in the art when the measurement has departed from accuracy requirements needed for a process monitor. It is possible then to attach a quality value to each measurement that results in acceptance or rejection of data. Feedback can occur to a system operator, which results in correction of the problem in the scanning electron microscope. The drift in accuracy costs will also be monitored and proactively addressed.

The present invention is also advantageous because it provides a method of analyzing a semiconductor surface having a patterned feature formed on a semiconductor layer, and calculating not only the scale, but also the shape of the patterned feature, based on the profile of the amplitude modulated waveform signal. The calculated scale and shape of the patterned feature is compared to a template derived from a normal patterned feature having a desired shape and scale,

As known to those skilled in the art, critical dimension metrology, such as line width and line spacing metrology, attempts to relate the intensity signal of an amplitude modulated waveform signal to the actual size of the feature, known as scale. The intensity signal formed as an amplitude modulated waveform signal is usually visualized and manipulated as a profile or waveform. The measurement of the size (i.e., scale) of a patterned feature, such as the cross-sections shown in FIGS. 8 and 9, involves the extraction of the etch positions from this waveform. These are shown in the top figure portion of FIGS. 8 and 9, illustrating the generated amplitude modulated waveform signal.

The traditional line width metrology, as known to those skilled in the art, ignores much of the effect caused by a variation of the shape of the feature as it is measured on the waveform signal to be analyzed. However, in accordance with the present invention, it is possible to deduce the shape of a feature from the waveform by using a sophisticated interpretation of the shape or profile of the waveform. The analysis of the critical dimension intensity signal formed as the amplitude modulated waveform signal allows a person not only to measure the specific width of a feature, i.e., the scale, as is well known to those skilled in the art, but also allows an operator to determine a better estimate as to the actual shape of the feature. Both photo and etch production process drift can thus be monitored, resulting in improved process and quality control before any gross failures in metrology occur.

Because of the miniaturization of devices with ultra large scale integrated circuits, technology is pushing critical dimension metrology into multiple parameter characterization. Thus, it is no longer adequate to determine only the distance between defined edges of a feature based upon the amplitude modulated waveform signal. The peak areas on the generated waveform signal typically correspond to the edges, which emit energy in greater intensity, as shown in the images of FIGS. 13-15 and 17. Samples with the same nominal critical dimension width, as measured by the line distance, could be different in cross-section shape (profile) and could also function differently in production. When used on a photoresist or a photo mask, these differences would influence the etch or photo transfer function, perhaps creating severe problems downstream in the production and perhaps device failure in device operation.

Throughout the description of the present invention, an intensity scanning electron microscope will be described, which outputs an intensity signal formed as an amplitude modulated waveform signal. However, any waveform signal can be interpreted in a similar manner, even as generated from physical contact instruments, such as stylus instruments, as described above.

FIG. 8 illustrates a normal patterned feature 150, such as formed on a photoresist, and the generated waveform signal 152. FIG. 9 illustrates a photoresist defect caused by T-topping in a photoresist patterned feature 154, which is caused by an amine contamination. Its generated waveform signal 156 is shown in the top portion of the figure. As illustrated, the scale is similar, but the generated waveforms 152, 156 deviate in shape in relation to the cross-sections 150, 154. It is this deviation and profile of the amplitude modulated waveform signals that can be analyzed to determine possible defects in the estimated shape of the patterned feature. The shape of the patterned feature can also be seen in the shape of the amplitude modulated waveform signal, where the shape of the components are extracted.

FIGS. 14 and 15 illustrate top down critical dimension line width images of a nested photoresist object both with and without T-top. FIG. 14 illustrates the T-top where the lines are more narrowly defined resulting from the sharp edges of the T-top reflecting light at greater intensity along a more narrow area, as compared to the normal configuration of a photoresist feature shown in FIG. 15.

There are several two-dimensional visual items that distinguish the two images, all of which can be detected from the one-dimensional line traces using signal processing techniques in a controller 132 that is connected to the scanning electron microscope. The controller 132 can use software and signal processing techniques known to those skilled in the art. The width of the white sidewall is considerably reduced in the case of the T-top because of the more sharp edge defined by the T-top. The edge roughness or width variation in the wide direction is also increased in the T-top example.

FIGS. 10 and 11 illustrate edge detection techniques where the line width 160 and line spacing 162 are illustrated (FIG. 10) as part of the amplitude modulated waveform signal. The derivative of the signal is taken along various points to derive a curve, indicating the line width and line space as shown in FIG. 11. The outside line width and inside line space describe the shape of the critical dimension variation of the line width.

By using a template (FIG. 12), it is possible to compare the T-top derived curve, with the derived curve of the template. Thus, the photoresist feature can be rejected based upon a deviation in a predetermined amount from the template curve. The graph of FIG. 12 indicates that greater deviation is along the line spacing. The notations of 50/1/1/1 are Hitachi specific shorthand for first and second differential edge components. The min/max is the range of critical dimension over a length of Y using a specific derivative based etch detection algorithm to describe roughness. The algorithm can be implemented by those techniques known to those skilled in the art.

Deviations of any specific critical dimension or sloped interval could be weighted in an analytical expression. Thus, any individual, small deviation would not trigger a fail, but an-accumulation of the deviations could trigger the fail. Some features could be weighted heavier to tune the metrology system to be robust against false-positive fail indications. For example, it would be possible to establish a string of Boolean decisions to determine the pass/fail outcome. For example, any deviation from a specified 10% to 30% width threshold slope could be specified as a fail regardless of the rest of the shape. This slope is known to be strongly related to the patterned transfer process and would be a critical parameter.

FIG. 13 illustrates another image of the output from the scanning electron microscope showing the overlay of the amplitude modulated waveform signal and the various width and space inflection points. The intensity is summed over 300 line scans. The 50% space and 50% width intensity marks 166, 168 are shown. The 100% intensity mark 170 is illustrated giving the line width in nanometers. The derivative dy/dx width 172 is used in linear approximation for etch detection and the maximum or minimum dy/dx marks are used in the inflection point. FIG. 16A shows a normal patterned feature 180, its generated waveform 182, and derived curve 184. FIG. 16B shows an example of a feature having a footing 186 and its amplitude modulated waveform signal 187 and its derived slope 188 with the footing change shown at 189. The dotted line represents the normal curve from the template. The photoresist feature 190 has a poor topping 191, as shown in FIG. 16C, and the change is shown at 192 in the derived curve 193.

FIG. 17 shows an image illustrating how a critical distance etch detection parameter could indicate a similar width for different structures, despite large variations in the profiles, i.e., the shape and pattern transfer.

Referring now to FIGS. 18 and 19, images of a positive stepper focus (FIG. 18) and negative stepper focus (FIG. 19) are shown. For example, the stepper focus may have drifted into the positive region in a photoresist system. This would result in a reduced thickness of the photoresist without a large change in the critical dimension width. During etch, the remaining thickness would not be sufficient to properly protect the transferred pattern due to a decreased photoresist thickness.

The method of the present invention would detect any significant waveform deviation and fail the entire lot before committing this lot to etching. Because the sensitivity of the process drift is increased, it would be possible to reduce the overdesigned margin of the photoresist thickness resulting in increased quality of the photo step. The increase in the thickness would no longer be necessary as part of the process. The metrology step of the present invention would also recognize deviations. Thus, as a result, a better overall pattern transfer would occur with less scrap due to unmonitored process variations.

A prior art metrology system using a single parameter line width control would not note the deviation and shape associated with the focus drift and loss of height. As noted before, the prior art single parameter line width metrology targets only an approximation of scale. It is well known that the smaller features contain significant proportion of width (or scaled) contribution in the shape of the object. The features of the same scale could pattern transfer the mask or photoresist level differently with different shapes.

The present invention is also advantageous because in the manufacturing process, the calculated shape and scale and positional distribution can be used for adjusting a subsequent etch process to compensate for any defects in the patterned feature. For example, when the T-top of FIGS. 9 and 14 is determined to exist, it is possible to change the subsequent etch process to compensate for this defect in the patterned feature. Not only does the invention distinguish scale and shape, but the present invention also allows a positional distribution of scale and shape to be determined based upon the scanning step. For example, the edges of the wafer could be larger than the center portion of the wafer, or the center portion may have a different shape than the edges or any combination. Thus, not only is the scale and shape important, but the positional distribution of the various defects are important for adjusting the etching process. For example, 100 sites on a wafer could be scanned forming a matrix. These 100 points are measured with the scale and shape and each of the 100 points would have a specific scale and specific shape. Thus, the etch personnel would have to know not only the scale and shape, but the positional distribution and that information would be used to adjust the etching process to account for the scale, shape and positional distribution.

The scanning electron microscope forms multiple measurements and is used for the computer calculation of the shape and size of the resist or other features as noted before. This information can be fed forward in a subsequent etch step, where the information is processed to decide on the most appropriate manufacturing process to improve shape, by adjusting different parameters such as the pressure, gas mixture and flow rates, power and magnetic field, for example, in a plasma etch process. Thus, certain abnormalities and defects present after lithography can be corrected in the etch process, imparting a more desirable scale and profile, i.e., shape, to the final patterned feature. This is in contrast to a conventional prior art method, where the photoresist would be removed and the lithography process would be repeated because in line width metrology systems, shape was not determined.

As shown in FIGS. 20A and 21A, it is possible to represent a photoresist distribution of patterned features of scale in a population distribution, and in a shape population distribution, as also shown in FIG. 21A. A matrix of scale and shape values based on a population distribution for a plurality of patterned features can be established as illustrated in FIG. 22. Thus, based upon the scale and shape values, it is possible to obtain an etch process recipe corresponding to a matrix value (e.g., C3) which demands a change in the etching process. The matrix shown in FIG. 22 becomes a recipe choice matrix for etching.

Typically, a patterned partition is divided by distribution into bins or different lots, with some lots small and some lots large. Thus, there exists a scale versus shape distribution, as shown in FIGS. 20A and 21A. If one knows that an incoming lot has a population distribution of patterned features corresponding to C3, then subsequent process changes will occur based on that variable. For example, C3 could be characterized by T-topping, or characterized by a larger scale and a more pronounced slope in the shape. Thus, the controller in the system of the present invention would direct that the C3 type of material is incoming to the etched que, and the particular shape and size based upon the C3 database would have to be changed. The combination of different etches would be available to compensate for the C3 type of photoresist pattern.

The type of changes in the etch process can vary. For example, the plasma density can be altered in the etch process to alter locally the etch rate and total etch. This can accommodate photo deviations from specifications by using feed forward metrology. There could be backside cooling zones of variable etch rate. Traditionally, the plasma stream is uniform across the wafer. It would be possible to use many independent electrodes for specific patterning or direct plasma with variable magnetic fields to alter the local density. The local gas pressure could be varied and wafer position for etching could be adjusted in some instances.

In some cases, it may be possible to create plasma in a separate reaction chamber, and direct it variably toward a point on the wafer, using a focusing or directional optional system with specific energy.

The present invention is also advantageous because a layer on the surface having patterned features can be analyzed via segments of the amplitude modulated waveform signal, as shown in FIG. 40. The analysis “by parts” allows a weighting of certain segments for emphasis. Thus, the physical relationships among the signal parts and the physical object can be separated, and any confusing aspects of scale can be eliminated. Thus, it is possible to separate shape from scale in the metrology system of the present invention.

For purposes of background, FIGS. 23-39 describe a whole signal correlation process (not by parts), which allows the measure of an entire amplitude modulated waveform signal with a reference signal formed of an amplitude modulated waveform signal. Further details of this system are set forth in U.S. patent application Ser. No. 08/957,122 filed Oct. 24, 1997, and entitled “SCANNING ELECTRON MICROSCOPE SYSTEM AND METHOD OF MANUFACTURING AN INTEGRATED CIRCUIT,” assigned to the present assignee, the disclosure which is hereby incorporated by reference in its entirety.

After describing the “whole” correlation, the description will proceed with the aspect of the present invention directed to the scanning electron microscope system shown in FIG. 2C, which measures and analyzes the surface topology of a wafer during the manufacturing process, and then correlates the signal deviations “by parts.”

The surface topology is first measured using a scanning electron microscope 10. The measured topology is then processed using signal processing techniques within controller 132 and compared to data from a standardized wafer which has been processed in the same manner and stored in database 139. Differences and errors in the wafer are manifested in the measured topology and may be detected by the comparison. As a result, processing monitoring may be improved and fatal errors in the wafers may be detected before further processing. Further, the above process may be implemented without adding additional steps to the manufacturing process, because the scanning electron microscope is already used during processing.

The scanning electron microscope (SEM) scans a wafer (e.g., the substrate) having a surface feature, and produces a wafer waveform signal y_(i) (t). The SEM is, for example, Model S8820 available from Hitachi of Japan. The SEM is coupled to the processor of controller 132, as is well known to those skilled in the art.

The processor receives the wafer waveform signal y_(i) (t) and detects errors and deficiencies in the wafer by analyzing the wafer waveform signal y_(i) (t). In addition, the processor may detect deviations in the manufacturing process such as variations between tools. This process may be performed in-line during the manufacturing process. “In-line during the manufacturing process” means during the process of forming circuitry on the wafer. Consequently, process errors and degraded quality in, for example, the lithography and etching processes may be detected before manufacture of the devices is completed.

In this way, adjustments may be made in the manufacturing line to correct, for example, tool drift and tool-to-tool matching for SEMs, steppers and etchers. This allows problems such as SEM charging, stepper out of focus, and over etch errors to be detected and corrected. Further, defective wafers may be detected and removed prior to further processing. In addition, wafer characterization may be performed to profile degradation across a wafer. As a result, the cost of the manufacturing process may be decreased while increasing the quality of the wafers produced.

As noted before, the SEM system also includes a database 139 for storing reference data. The SEM system may also include a tool or tools 134 that may be automatically or manually adjusted in response to the analysis performed by the SEM system. The components may be combined into one or more components, and may be implemented in hardware or software as known to those skilled in the art.

The SEM acquires the wafer waveform signal y_(i)(t) by scanning. An example of a waveform for a charged resist line is shown in FIG. 24, while FIG. 23 shows one possible standard waveform, such as a reference or “template.” The processor generates a processed waveform signal p₂₂ from the wafer waveform signal y_(i) (t), by implementing a cross-correlation operation. In this way, phase errors (picture offsets) which may occur in the SEM can be eliminated. As a result, the wafer waveform signal y_(i) (t) may be compared to a standard waveform signal p₁₁.

The processor processes the wafer waveform signal y_(i) (t) using, for example, equation (1) below to produce a converted waveform signal Y_(i) (jw).

F[Y_(i)(t)]=Y_(i)(jw)  (1)

Equation (1) implements a Fast Fourier Transform (FFT). FIG. 26 is an exemplary converted waveform Y_(i) (jw) shown in FIG. 25. The converted waveform signal Y_(i) (jw) is filtered using a low pass filter as is shown in equation (2) below to produce a filtered waveform signal Y_(f) (jw).

F[Y_(i)(jw)]=Y_(f)(jw)  (2)

For example, the filter implemented by equation (2) may pass a quarter (¼) or less of the components of the converted waveform signal Y_(i) (jw). The high frequency components are removed to reduce the noise in the wafer waveform signal Y_(i) (t). FIG. 27 is the filtered waveform signal Y_(f) (jw) corresponding to the converted waveform signal Y_(i) (jw) shown in FIG. 26.

An auto-correlation operation is performed to produce a wafer auto-correlation signal R₂₂ (jw) from the filtered waveform signal Y_(f) (jw) using equation (3) below.

R₂₂(jw)=Y_(f)(jw)Y*_(f)(jw)  (3)

In equation (3), the “*” indicates a complex conjugate. An exemplary wafer auto-correlation signal R₂₂ (jw) is shown in FIG. 28. An inverse transform is performed to produce a transformed signal r₂₂ (t) using equation (4) below: $\begin{matrix} {{r_{22}(t)} = {F^{- 1}\left\lbrack \frac{R_{22}\left( {j\quad w} \right)}{N} \right\rbrack}} & (4) \end{matrix}$

In equation (4), N is the total number of pixels that would be used for displaying the waveform or the total number of input quantities (samples). For example, an exemplary transformed signal r₂₂ (t) is shown in FIG. 29.

The maximum value MAX₂₂ of the transformed signal r₂₂ (t) is determined at a phase or lag equal to, for example, zero (0) as is shown in equation (5) below.

MAX₂₂=r₂₂(t)(t=0)  (5)

The transformed signal r₂₂ (t) is normalized according to equation (6) below to produce the processed waveform signal p₂₂. $\begin{matrix} {{P_{22}(t)} = \frac{r_{22}(t)}{{MAX}_{22}}} & (6) \end{matrix}$

An exemplary transformed signal r₂₂ (t) is shown in FIG. 30 where the transformed signal r₂₂ (t) is normalized for probability densities for a lag of i. The maximum value MAX₂₂ could be, for example, 332.164.

The processed waveform signal p₂₂ is compared to a standard waveform signal p₁₁. The standard waveform signal p₁₁ is used as a bench mark to determine whether other wafers have deficiencies and satisfy quality standards and to detect variations in the manufacturing process. The standard waveform signal p₁₁ is derived from a scan of a standard wafer (not shown). The standard wafer is a wafer that satisfies the desired manufacturing criteria for producing the wafer. In other-words, the wafer is acceptable if the wafer is within a specified range of the standard wafer. The process for deriving the standard waveform signal p₁₁ is the same as the process for producing the processed waveform signal p₂₂ except the process is performed on a scanned signal from the standard wafer.

FIGS. 31-36 are exemplary waveforms corresponding to the process steps used in deriving the standard waveform signal p₁₁. FIG. 31 is an exemplary wafer waveform signal x_(i) (t) for a resist line on the standard wafer. The resist line is not charged. FIG. 32 is an exemplary converted waveform X_(i) (jw) for the wafer waveform signal x_(i) (t) shown in FIG. 31. FIG. 33 is the filtered waveform signal X_(f) (jw) corresponding to the converted waveform signal X_(i) (jw) shown in FIG. 33. FIG. 34 is the wafer auto-correlation signal R₁₁ (jw) for the filtered waveform signal X_(f) (jw) shown in FIG. 33. The transformed signal r₁₁ (t) of the auto-correlation signal R₁₁ (jw) is shown in FIG. 35. Finally, FIG. 36 shows the standard waveform signal R₁ (t) corresponding to the transformed signal r₁₁ (t) shown in FIG. 35. The maximum value MAX₁₁ used to produce the standard waveform signal R₁₁ (t) shown in FIG. 29 could be 551.405.

The processor then determines whether the comparison waveform signal p₁₂ is within a predetermined range. A cross-correlation signal R₁₂ (jw) is generated from the processed waveform signal p₂₂ and the standard waveform signal p₁₁ by converting them to the frequency domain and using equation (7) below.

R₁₂=X_(f)(jw)Y*_(f)(jw)  (7)

“*” indicates the complex conjugate. FIG. 37 is an exemplary cross-correlation signal R₁₂ (jw) of the processed waveform signal p₂₂ and the standard waveform signal p₁₁.

The cross-correlation signal R₁₂ (jw) is converted to the time domain using equation (8) below to produce the inverse cross-correlation signal r₁₂ (t). $\begin{matrix} {{r_{12}(t)} = {F^{- 1}\left\lfloor \frac{R_{12}\left( {j\quad w} \right)}{N} \right\rfloor}} & (8) \end{matrix}$

FIG. 38 is the inverse cross-correlation signal r₁₂ (t) corresponding to the cross-correlation signal R₁₂ (jw) shown in FIG. 37.

The inverse cross-correlation signal r₁₂ (t) is normalized according to equation (9) below. $\begin{matrix} {{P_{12}(t)} = \frac{r_{12}(t)}{{MAX}_{func}}} & (9) \end{matrix}$

The value Max_(func) is defined in equation (10) below.

Max₁₂ if Max₂₂<Max₁₂ and to compare shape and amplitude Max_(func)=Max₂₂ if Max₁₂<Max₂₂ and to compare shape and amplitude Square Root of Max₂₂*Max₁₁ if only to compare shape  (10)

FIG. 39 shows the normalized signal p₁₂ (t) normalized using a Max_(func) of 551.405 (square root of Max₂₂ multiplied by Max₁₁). The shape of the waveforms are only compared if there is a degradation in the SEM or the SEM is not matched to the SEM that measured the standardized wafer. The maximum value p_(max) of the comparison waveform signal p₁₂ (t) is determined. The maximum value p_(max) for the normalized signal p₁₂ (t) shown in FIG. 22 is 0767.

The processor determines whether the comparison waveform signal is within specification. For example, if the absolute value of the maximum value p_(max) is greater than 0.9 and less than 1 (0.90<|p_(max)|<1), the wafer is considered acceptable. In a production line arrangement, one or more wafers may be tested to determine if an entire lot is acceptable. Otherwise, the lot may be rejected. Typically, acceptable wafers have been found to have a maximum value p_(max) between 0.95 and 1 (0.95<|p_(max)|<1)

The lot or tools are indicated as passing if the maximum value p_(max) is within the specified range. Otherwise, the maximum value p_(max) is compared to data stored in database to determine what error has occurred and how the error may be corrected. The database includes data and/or instructions for modifying the production process to eliminate the errors. The processor provides instructions to the tools, equipment, etc. using the data from the database to correct the errors. Alternatively, the information may be provided to an operator via a user interface (not shown). The operator makes adjustments to the manufacturing process in response to the information.

If there is no corresponding instructions for correcting the error, the error and the associated data are stored in the database for future analysis and comparison. For example, the wafer waveform signal y_(i) (t), the comparison waveform signal p₁₂, and/or any of the other signals produced or used during the analysis of the wafer may be stored.

There now follows a more detailed description of the auto-correlation “by parts.”

FIG. 40 shows how the amplitude modulated waveform signal is split into segmented parts numbered 1 a-5 a, followed by a second waveform of a second patterned feature beginning with 1 b.

FIGS. 41A, 41B and 41C show the comparison of contoured shapes and scale (FIG. 41A) with the template using parts 2 a and 6 a. The curve is derived as shown in FIGS. 41B and 41C and consideration given to d(int)/dx, d²/dx . . . The input template and variables can be passed as signals to an EXCEL macro by pointing to a data directory. Input choices and analysis can be placed in a dialog box, as known to those skilled in the art. The output would be to a correlation value. FIG. 42 shows the same shape with a different scale, and FIG. 43 shows the same scale with different shapes. FIG. 44 shows a graph of the correlation by derivative that emphasizes the slope and transitions to have reduced tool differences. The amplitude can be normalized with a different emphasis on slope contribution to the shape. FIG. 45 shows the detection of specific shapes, such as the scum and focus variations, and emphasizes the difference in waveforms.

FIG. 46 is a graph illustrating the derivative correlation after the normalization to d(int)/dx where the amplitude accounts for variations in the tool (SEM) waveform signal gain that have similar sharpness.

The following data illustrates the type of signal correlation module and the various mechanics and normalization that can be used to develop the software for the present invention as described. The FFT corresponds to the Fast Fourier Transform.

Correlation Mechanics

WF₁ template waveform, whole signal & Partitioned & derivatives

WF_(N) signal waveforms to be tested N=2,3,4 . . .

FFT (WF₁) (Conj FFT (WF₁) Autocorrelation 1:1

FFT (WF₂) (Conj FFT (WF₂) Autocorrelation N:N

Correlation 1:2 FFT (WF₁) (Conj FFT (WF₂)

Inverse Autocorr. 1:1, Determine MAX 1:1, lag=0

Inverse Autocorr 2:2, Determine MAX 2:2, lag=0

Inverse Corr 1:2, Determine MAX 1:2, lage=output this value

Normalization:

To compare amplitude and shape Max 1:1 or Max 2:2 shape but not amplitude

{square root over (MAX11+L ×MAX22+L )}

Simple Correlation: $\frac{{Max}\quad 12}{{Max}\quad 11}\quad {or}\quad \frac{{Max}\quad 12}{{Max}\quad 22}\quad {or}\quad \frac{MAX12}{\sqrt{{MAX11} \times {MAX22}}}$

Alternate: remove DC component from WF1 & WFN by subtracting WF mean before Auto correlation steps. (Tool offset gain)

Padding: to avoid end effects the initial WF should be padded with its mean value out to the next 2 ^(N) integer value. Smoothing the padded transition avoids extra frequence, components.

Signal Partition: to correlate shape apart from scale it is necessary to correlate the WF signal by parts.

Signal Derivatives: d(lnt)/dx, d² (lnt)/dx and partitions can be correlated to emphasize shape relations while removing tool differences in signal range (amplitude).

This application is related to copending patent applications entitled, “METHOD OF ANALYZING SEMICONDUCTOR SURFACE WITH PATTERNED FEATURE USING LINE WIDTH METROLOGY,” “METHOD FOR MANUFACTURING SEMICONDUCTOR INTEGRATED CIRCUITS WITH ETCH PROCESS MODIFICATION,” and “METHOD ANALYZING A SEMICONDUCTOR SURFACE USING LINE WIDTH METROLOGY WITH AUTO-CORRELATION OPERATION,” which are filed on the same date and by the same assignee, the disclosures which are hereby incorporated by reference.

Many modifications and other embodiments of the invention will come to the mind of one skilled in the art having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is to be understood that the invention is not to be limited to the specific embodiments disclosed, and that the modifications and embodiments are intended to be included within the scope of the dependent claims. 

That which is claimed is:
 1. A method of determining the accuracy error in scanned signals of a semiconductor line width metrology device comprising the steps of: creating a frequency signature template of a known patterned feature having a central portion, edge portions and very edge formed on a semiconductor layer with a line width metrology measurement device that is in a nominal operating condition by obtaining amplitude modulated waveform signals for the central portion, edge portions and very edge and converting the amplitude modulated waveform signals into low, mid-range and high frequency components corresponding to respective central and edge portions and very edges; scanning another similar patterned feature having a central portion, edge portions, and very edge formed on a semiconductor layer with the line width metrology measurement device for generating amplitude waveform signals of the line width of the similar patterned feature for the central portion, edge portions and very edge; processing the waveform signal to convert the waveform signal into a frequency signature having low, mid-range and high frequency components corresponding to respective central and edge portions and very edge; comparing the relative power of the frequency components of the frequency signature obtained from the similar patterned feature with the relative power of the frequency signature template; and determining the accuracy of the line width metrology device based on the relative proportions between the high frequency signatures of the known and similar patterned feature.
 2. A method according to claim 1, and further comprising the step of determining the relative proportions between the low and high frequencies of the frequency signature template and comparing the relative proportions of the low and high frequencies of the frequency signature template with the frequency signature obtained from the similar patterned feature.
 3. A method according to claim 2, and further comprising the step of determining the relative proportions of high and low frequencies with the mid-range frequencies corresponding to the inner line spacing.
 4. A method according to claim 1, and further comprising the step of comparing the high frequencies within the frequency signature template with the high frequencies in the frequency signature obtained from the similar patterned feature.
 5. A method according to claim 1, and wherein the step of scanning further comprises the step of generating an amplitude modulated waveform.
 6. A method according to claim 5, and further comprising the step of generating the waveform signals from a scanning electron microscope.
 7. A method according to claim 5, and further comprising the step of generating the signals from a semiconductor stylus measurement tool.
 8. A method of determining the accuracy error in scanned signals of a semiconductor line width metrology device comprising the steps of: scanning a known patterned feature having a central portion, edge portions, and very edge formed on a semiconductor layer with a line width metrology device that is in a nominal operating condition by obtaining amplitude modulated waveform signals for the central portion, edge portions and very edge and converting the amplitude modulated waveform signals into low, mid-range and high frequency components corresponding to central and edge portions and very edge; scanning a similar patterned feature having a central portion, edge portions, and very edge formed on a semiconductor layer with the line width metrology measurement device for generating amplitude waveform signals indicative of the central portion, edge portions, and very edges of the similar patterned feature; processing the amplitude waveform signals to convert the signals into a frequency signature having low, mid-range and high frequency components corresponding to respective central and edge portions and very edge; comparing the relative power of the high frequency components of the frequency signature obtained from the similar patterned feature to the high frequency components of the frequency signature template obtained from the known sample; and determining the accuracy of the line width metrology tool based on the relative proportions between the high frequency components of the frequency signatures of the similar patterned feature and template.
 9. A method according to claim 8, and further comprising the step of determining the relative proportions between the low and high frequencies of the frequency signature template and comparing the relative proportions of the low and high frequencies of the frequency signature template obtained from the similar patterned feature.
 10. A method according to claim 9, and further comprising the steps of determining the relative proportions of high and low frequencies with the mid-range frequencies corresponding to the inner line spacing.
 11. A method according to claim 9, and further comprising the step of comparing the high frequencies within the frequency template with the high frequencies in the frequency signature obtained from the similar patterned feature.
 12. A method according to claim 8, and wherein the step of scanning further comprises the step of generating an amplitude modulated waveform.
 13. A method according to claim 12, and further comprising the step of generating the signals from a scanning electron microscope.
 14. A method according to claim 12, and further comprising the step of generating the signals from a semiconductor stylus measurement tool. 